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8/10/2019 Notes PDE Pt4
1/37
2008, 2012 Zachary S Tseng E-4 - 1
Second Order Linear Partial Differential Equations
Part IV
One-dimensional undamped wave equation; DAlembert solution of the
wave equation; damped wave equation and the general wave equation; two-
dimensional Laplace equation
The second type of second order linear partial differential equations in 2
independent variables is the one-dimensional wave equation. Together with
the heat conduction equation, they are sometimes referred to as theevolutionequations because their solutions evolve, or change, with
passing time. The simplest instance of the one-dimensional wave equation
problem can be illustrated by the equation that describes the standing wave
exhibited by the motion of a piece of undamped vibrating elastic string.
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Undamped One-Dimensional Wave Equation:
Vibrations of an Elastic String
Consider a piece of thin flexible string of lengthL, of negligible weight.Suppose the two ends of the string are firmly secured (clamped) at some
supports so they will not move. Assume the set-up has no damping. Then,
the vertical displacement of the string, 0 0.
The two boundary conditions reflect that the two ends of the string are
clamped in fixed positions. Therefore, they are held motionless at all time.
The equation comes with 2 initial conditions, due to the fact that it contains
the second partial derivative term utt. The two initial conditions are the
initial (vertical) displacement u(x,0), and the initial (vertical) velocity
ut(x,0), both are arbitrary functions ofxalone. (Note that the string is
merely the medium for the wave, it does not itself move horizontally, it onlyvibrates, vertically, in place. The resulting wave form, or the wave-like
shape of the string, is what moves horizontally.)
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Hence, what we have is the following initial-boundary value problem:
(Wave equation) a2
uxx= utt , 0
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Dividing both sides by a2
X T:
Ta
T
X
X2
=
As for the heat conduction equation, it is customary to consider the constant
a2as a function of tand group it with the rest of t-terms. Insert the constant
of separation and break apart the equation:
=
=
Ta
T
X
X2
=
X
X X = X X +X= 0,
=
Ta
T2 T = a
2T T + a
2T= 0.
The boundary conditions also separate:
u(0,t) = 0 X(0)T(t) = 0 X(0) = 0 or T(t) = 0
u(L,t) = 0 X(L)T(t) = 0 X(L) = 0 or T(t) = 0
As usual, in order to obtain nontrivial solutions, we need to choose
X(0) = 0 andX(L) = 0 as the new boundary conditions. The result,
after separation of variables, is the following simultaneous system of
ordinary differential equations, with a set of boundary conditions:
X +X= 0, X(0) = 0 and X(L) = 0,
T + a2
T= 0.
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The next step is to solve the eigenvalue problem
X +X= 0, X(0) = 0, X(L) = 0.
We have already solved this eigenvalue problem, recall. The solutions are
Eigenvalues: 2
22
L
n = , n= 1, 2, 3,
Eigenfunctions:L
xnXn
sin= , n= 1, 2, 3,
Next, substitute the eigenvalues found above into the second equation to find
T(t). After putting eigenvaluesinto it, the equation of Tbecomes
02
222 =+ T
naT
.
It is a second order homogeneous linear equation with constant coefficients.
Its characteristic have a pair of purely imaginary complex conjugate roots:
iL
anr
= .
Thus, the solutions are
L
tanB
L
tanAtT nnn
sincos)( += , n= 1, 2, 3,
Multiplying each pair ofXnand Tntogether and sum them up, we find thegeneral solution of the one-dimensional wave equation, with both ends fixed,
to be
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=
+=
1
sinsincos),(n
nnL
xn
L
tanB
L
tanAtxu
.
There are two sets of (infinitely many) arbitrary coefficients. We can solve
for them using the two initial conditions.
Set t= 0 and apply the first initial condition, the initial (vertical)
displacement of the string u(x,0) =f(x), we have
( )
=
=
==
+=
1
1
)(sin
sin)0sin()0cos()0,(
n
n
nnn
xfL
xnA
L
xn
BAxu
Therefore, we see that the initial displacementf(x) needs to be a Fourier sine
series. Sincef(x) can be an arbitrary function, this usually means that we
need to expand it into its odd periodic extension (of period 2L). The
coefficientsAnare then found by the relationAn= bn, where bnare thecorresponding Fourier sine coefficients off(x). That is
==L
nn dxL
xnxf
LbA
0
sin)(2
.
Notice that the entire sequence of the coefficientsAnare determined exactly
by the initial displacement. They are completely independent of the othersequence of coefficientsBn, which are determined solely by the second
initial condition, the initial (vertical) velocity of the string. To findBn, we
differentiate u(x,t) with respect to tand apply the initial velocity,
ut(x,0) =g(x).
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=
+=
1
sincossin),(n
nntL
xn
L
tan
L
anB
L
tan
L
anAtxu
Set t= 0 and equate it withg(x):
)(sin)0,(1
xgL
xn
L
anBxu
n
nt ==
=
.
We see thatg(x) needs also be a Fourier sine series. Expand it into its odd
periodic extension (period 2L), if necessary. Onceg(x) is written into a sine
series, the previous equation becomes
=
=
===11
sin)(sin)0,(n
n
n
ntL
xnbxg
L
xn
L
anBxu
Compare the coefficients of the like sine terms, we see
==L
nn dxL
xnxg
Lb
L
anB
0
sin)(2
.
Therefore,
==L
nn dxL
xnxg
anb
an
LB
0
sin)(2
.
As we have seen, half of the particular solution is determined by the initialdisplacement, the other half by the initial velocity. The two halves are
determined independent of each other. Hence, if the initial displacement
f(x) = 0, then allAn= 0 and u(x,t) contains no sine-terms of t. If the initial
velocityg(x) = 0, then allBn= 0 and u(x,t) contains no cosine-terms of t.
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Let us take another look and summarize the result for these 2 easy special
cases, when eitherf(x) org(x) is zero.
Special case I: Nonzero initial displacement, zero initial velocity: f(x) 0,
g(x) = 0.
Sinceg(x) = 0, thenBn= 0 for all n.
=L
n dxL
xnxf
LA
0
sin)(2
, n= 1, 2, 3,
Therefore,
=
=1
sincos),(n
nL
xn
L
tanAtxu
.
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The DAlembert Solution
In 1746, Jean DAlembert produced an alternate form of solution to the
wave equation. His solution takes on an especially simple form in the abovecase of zero initial velocity.
Use the product formula sin(A)cos(B) = [sin(AB) + sin(A+B)]/2, the
solution above can be rewritten as
=
++
=
1
)(sin
)(sin
2
1),(
n
nL
atxn
L
atxnAtxu
Therefore, the solution of the undamped one-dimensional wave equation
with zero initial velocity can be alternatively expressed as
u(x,t) = [F(x at) +F(x+ at)]/2.
Such thatF(x) is the odd periodic extension (period 2L) of the initial
displacementf
(x).
An interesting aspect of the DAlembert solution is that it readily shows that
the starting waveform given by the initial displacement would keep its
general shape, but it would also split exactly into two halves. The two
halves of the wave form travel in the opposite directions at the same finite
speed of a. (Notice that the two halves of the wave form are being
translated/moved in the opposite direction at the rate of distance aper unit
time.)
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Special case II: Zero initial displacement, nonzero initial velocity: f(x) = 0,
g(x) 0.
Sincef(x) = 0, thenAn= 0 for all n.
=L
n dxL
xnxg
anB
0
sin)(2
, n= 1, 2, 3,
Therefore,
=
=1
sinsin),(n
n
L
xn
L
tanBtxu
.
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Example: Solve the one-dimensional wave problem
9uxx= utt , 0 0,
u(0,t) = 0, and u(5,t) = 0,
u(x,0) = 4sin(x) sin(2x) 3sin(5x),ut(x,0) = 0.
First note that a2
= 9 (so a= 3), andL= 5.
The general solution is, therefore,
=
+=
1 5sin
53sin
53cos),(
n
nn xntnBtnAtxu .
Sinceg(x) = 0, it must be that allBn= 0. We just need to findAn. We
also see that u(x,0) =f(x) is already in the form of a Fourier sine
series. Therefore, we just need to extract the corresponding Fourier
sine coefficients:
A5= b5= 4,A10= b10= 1,
A25=b25= 3,
An= bn= 0, for all other n, n 5, 10, or 25.
Hence, the particular solution is
u(x,t) = 4cos(3t)sin(x) cos(6t)sin(2x)
3cos(15t)sin(5x).
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We can also solve the previous example using DAlemberts solution. The
problem has zero initial velocity and its initial displacement has already been
expanded into the required Fourier sine series, u(x,0) = 4sin(x) sin(2x)
3sin(5x) =F(x). Therefore, the solution can also be found by using the
formula u(x, t) = [F(x at) +F(x+ at)]/2, where a= 3. Thus
u(x,t) = [ [ 4sin((x+ 3t)) + 4sin((x 3t)) ] [sin(2(x+
3t)) + sin(2(x+ 3t)) ] [3sin(5(x+ 3t)) + 3sin(5(x+
3t)) ] ]/2
Indeed, you could easily verify (do this as an exercise) that the solutionobtained this way is identical to our previous answer. Just apply the addition
formula of sine function ( sin() = sin()cos() cos()sin() ) to eachterm in the above solution and simplify.
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Example: Solve the one-dimensional wave problem
9uxx= utt , 0 0,
u(0,t) = 0, and u(5,t) = 0,
u(x,0) = 0,ut(x,0) = 4.
As in the previous example, a2
= 9 (so a= 3), andL= 5.
Therefore, the general solution remains
=
+=
1 5sin
5
3sin
5
3cos),(
n
nn
xntnB
tnAtxu
.
Now,f(x) = 0, consequently allAn= 0. We just need to findBn. The
initial velocityg(x) = 4 is a constant function. It is not an odd periodic
function. Therefore, we need to expand it into its odd periodic
extension (period T= 10), then equate it with ut(x,0). In short:
=
==
==
evenn
oddnn
dx
xn
ndxL
xn
xganB
L
n
,0
,3
80
5sin43
2
sin)(
2
22
5
00
Therefore,
=
=
122 5
)12(sin
5
)12(3sin
)12(3
80),(
n
xntn
ntxu
.
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The Structure of the Solutions of the Wave Equation
In addition to the fact that the constant ais the standing waves propagation
velocity, several other observations can be readily made from the solution ofthe wave equation that give insights to the nature of the solution.
To reduce the clutter, let us look at the form of the solution when there is no
initial velocity (wheng(x) = 0). The solution is
=
=1
sincos),(n
nL
xn
L
tanAtxu
.
The sine terms are functions ofx. They described the spatial wave patterns
(the wavy shape of the string that we could visually observe), called the
normal modes, or natural modes. The frequencies of those sine waves that
we could see, n/L, are called thespatial frequenciesof the wave.
Meanwhile, the cosine terms are functions of t, they give the vertical
displacement of the string relative to its equilibrium position (which is just
the horizontal, or thex-axis). They describe the up-and-down vibrating
motion of the string at each point of the string. These temporal frequencies(the frequencies of functions of t; in this case, the cosines) are the actual
frequencies of oscillating motion of vertical displacement. Since this is the
undamped wave equation, the frequencies of the cosine terms, an/L
(measured in radians per second), are called the natural frequenciesof the
string. In a string instrument, they are the frequencies of the sound that we
could hear. The corresponding natural periods (= 2/natural frequency) are
therefore 2L/an.
For n= 1, the observable spatial wave pattern is sin(x/L). It is the strings
first natural mode. The first natural frequency of oscillation, a/L, is called
thefundamental frequencyof the string. It is also called, in acoustics, as the
first harmonicof the string.
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For n= 2, the spatial wave pattern is sin(2x/L) is the second natural mode.
The second natural frequency of oscillation, 2a/L, is also called the second
harmonic (or thefirst overtone) of the string. It is exactly twice of the
strings fundamental frequency. Acoustically, it produces a tone that is one
octave higher than the first harmonic. For n= 3, the third natural frequencyis also called the third harmonic (or the second overtone), and so forth.
The motion of the string is the combination of all its natural modes, as
indicated by the general solution.
Lastly, notice that the wavelike behavior of the solution of the undamped
wave equation, quite unlike the solution of the heat conduction equation
discussed earlier, does not decrease in amplitude/intensity with time. Itnever reaches a steady state. This is a consequence of the fact that the
undamped wave motion is a thermodynamically reversible process that
needs not obey the second law of Thermodynamics.
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First natural mode (oscillates at the fundamental frequency / 1st harmonic):
Second natural mode (oscillates at the 2nd natural frequency / 2nd harmonic):
Third natural mode (oscillates at the 3rd natural frequency / 3rd harmonic):
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Summary of Wave Equation: Vibrating String Problems
The vertical displacement of a vibrating string of lengthL, securely clamped
at both ends, of negligible weight and without damping, is described by thehomogeneous undamped wave equation initial-boundary value problem:
a2
uxx= utt , 0
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The General Wave Equation
The most general form of the one-dimensional wave equation is:
a uxx+F(x,t) = utt+ ut+ ku.
Where a= the propagation velocity of the wave,
= the damping constant
k= (external) restoration factor, such as when vibrations occur
in an elastic medium.
F(x, t) = arbitrary external forcing function (IfF= 0 then the
equation is homogeneous, else it is nonhomogeneous.)
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The Telegraph Equation
The most well-known example of (a homogeneous version of) the general
wave equation is the telegraph equation. It describes the voltage u(x, t)inside a piece of telegraph / transmission wire, whose electrical properties
per unit length are: resistanceR, inductanceL, capacitance C, and
conductance of leakage current G:
a2
uxx= utt+ ut+ ku.
Where a2= 1/LC, = G/C+R/L, and k= GR/CL.
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Example: The One-Dimensional Damped Wave Equation
a2
uxx= utt+ ut, 0.
Suppose boundary conditions remain as the same (both ends fixed): (0,t) = 0,and u(L,t) = 0.
The equation can be separated as follow. First rewrite it as:
a2XT= XT + XT,
Divide both sides by a
2
X
T
, and insert a constant of separation:
=+
=
Ta
TT
X
X2 .
Rewrite it into 2 equations:
X= X X+X= 0,
T+ T= a2T T +T + a
2T= 0.
The boundary conditions also are separated, as usual:
u(0,t) = 0 X(0)T(t) = 0 X(0) = 0 or T(t) = 0
u(L,t) = 0 X(L)T(t) = 0 X(L) = 0 or T(t) = 0
As before, setting T(t) = 0 would result in the constant zero solution
only. Therefore, we must choose the two (nontrivial) conditions in
terms ofx: X(0) = 0, and X(L) = 0.
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After separation of variables, we have the system
X +X= 0, X(0) = 0 and X(L) = 0,
T + T
+ 2T= 0.
The next step is to find the eigenvalues and their corresponding
eigenfunctions of the boundary value problem
X +X= 0, X(0) = 0 and X(L) = 0.
This is a familiar problem that we have encountered more than oncepreviously. The eigenvalues and eigenfunctions are, recall,
Eigenvalues: 2
22
L
n = , n= 1, 2, 3,
Eigenfunctions:L
xnXn
sin= , n= 1, 2, 3,
The equation of t, however, has different kind of solutions depending on the
roots of its characteristic equation.
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Nonhomogeneous Undamped Wave Equation (Optional topic)
Problems of partial differential equation that contains a nonzero forcing
function (which would make the equation itself a nonhomogeneous partialdifferential equation) can sometimes be solved using the same idea that we
have used to handle nonhomogeneous boundary conditions by considering
the solution in 2 parts, a steady-state part and a transient part. This is
possible when the forcing function is independent of time t, which then
could be used to determine the steady-state solution. The transient solution
would then satisfy a certain homogeneous equation. The 2 parts are thus
solved separately and their solutions are added together to give the final
result. Let us illustrate this idea with a simple example: when the stringsweight is no longer negligible.
Example: A flexible string of lengthLhas its two ends firmly secured.
Assume there is no damping. Suppose the string has a weight density of 1
Newton per meter. That is, it is subject to, uniformly across its length, a
constant force ofF(x,t) = 1 unit per unit length due to its own weight.
Let u(x,t) be the vertical displacement of the string, 0
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steady-state displacement, v(x). Hence, we can rewrite the solution
u(x,t) as:
u(x,t) = v(x) + w(x,t).
By setting tto be a constant and rewrite the equation and the boundaryconditions to be dependent ofxonly, the steady-state solution v(x)
must satisfy:
a2
v+ 1 = 0,
v(0) = 0, v(L) = 0.
Rewrite the equation as v = 1/a2, and integrate twice, we get
212
221)( CxCx
axv ++
= .
Apply the boundary conditions to find C1=L/2a2and C2= 0:
xa
Lx
axv
2
2
2 22
1)( +
= .
Comment: Thus, the sag of a wire or cable due to its own weight can be
seen as a manifestation of the steady-solution of the wave equation. The sag
is also parabolic, rather than sinusoidal, as one might have reasonably
assumed, in nature.
We can then subtract out v(x) from the equation, boundary conditions,
and the initial conditions (try this as an exercise), the transient
solution w(x,t) must satisfy:
a2
wxx= wtt , 0
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The problem is now transformed to the homogeneous problem we
have already solved. The solution is just
=
+= 1 sinsincos),( nnn L
xn
L
tan
BL
tan
Atxw
.
Combining the steady-state and transient solutions, the general
solution is found to be
=
+++
=
+=
12
2
2sinsincos
22
1
),()(),(
n
nn
L
xn
L
tanB
L
tanAx
a
Lx
a
twxvtxu
The coefficients can be calculated and the particular solution
determined by using the formulas:
( ) =L
n dxL
xnxvxf
LA
0
sin)()(2
, and
=L
n dxL
xnxg
anB
0
sin)(2
.
Note: Since the velocity ut(x, t) = vt(x) + wt(x, t) = 0 + wt(x, t) = wt(x, t). The
initial velocity does not need any adjustment, as ut(x, 0) = wt(x, 0) =g(x).
Comment: We can clearly see that, even though a nonzero steady-state
solution exists, the displacement of the string will not converge to it as
t .
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The Laplace Equation / Potential Equation
The last type of the second order linear partial differential equation in 2
independent variables is the two-dimensionalLaplace equation, also calledthepotential equation. Unlike the other equations we have seen, a solution
of the Laplace equation is always a steady-state (i.e. time-independent)
solution. Indeed, the variable tis not even present in the Laplace equation.
The Laplace equation describes systems that are in a state of equilibrium
whose behavior does not change with time. Some applications of the
Laplace equation are finding the potential function of an object acted upon
by a gravitational / electric / magnetic field, finding the steady-state
temperature distribution of the (2- or 3-dimensional) heat conductionequation, and the steady-state flow of an ideal fluid.
Since the time variable is not present in the Laplace equation, any problem
of the Laplace equation will not, therefore, have an initial condition. A
Laplace equation problem has only boundary conditions.
Let u(x,y) be the potential function at a point (x,y), then it is governed by
the two-dimensional Laplace equation
uxx+ u y= 0.
Any real-valued function having continuous first and second partial
derivatives that satisfies the two-dimensional Laplace equation is called a
harmonic function.
Similarly, suppose u(x,y,z) is the potential function at a point (x,y,z), then it
is governed by the three-dimensional Laplace equation
uxx+ uyy+ uzz= 0.
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Comment: The one-dimensional Laplace equation is rather dull. It is merely
uxx= 0, where uis a function ofxalone. It is not a partial differential
equation, but rather a simple integration problem of u = 0. (What is its
solution? Where have we seen it just very recently?)
The boundary conditions that accompany a 2-dimensional Laplace equation
describe the conditions on the boundary curve that encloses the 2-
dimensional region in question. While those accompany a 3-dimensional
Laplace equation describe the conditions on the boundary surface that
encloses the 3-dimensional spatial region in question.
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The Relationships among Laplace, Heat, and Wave Equations
(Optional topic)
Now let us take a step back and see the bigger picture: how thehomogeneous heat conduction and wave equations are structured, and how
they are related to the Laplace equation of the same (spatial) dimension.
Suppose u(x,y) is a function of two variables, the expression uxx+ uyyis
called theLaplacianof u. It is often denoted by
2u= uxx+ uyy.
Similarly, for a three-variable function u(x,y,z), the 3-dimensional Laplacian
is then
2u= uxx+ uyy+ uzz.
(As we have just noted, in the one-variable case, the Laplaian of u(x),
degenerates into 2u= u.)
The homogeneous heat conduction equations of 1-, 2-, and 3- spatial
dimension can then be expressed in terms of the Laplacians as:
22u= ut,
where 2is the thermo diffusivity constant of the conducting material.
Thus, the homogeneous heat conduction equations of 1-, 2-, and 3-
dimension are, respectively,
2
uxx= ut
2
(uxx+ uyy) = ut
2
(uxx+ uyy+ uzz) = ut
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As well, the homogeneous wave equations of 1-, 2-, and 3- spatial dimension
can then be similarly expressed in terms of the Laplacians as:
a22u= utt,
where the constant ais the propagation velocity of the wave motion. Thus,
the homogeneous wave equations of 1-, 2-, and 3-dimension are,
respectively,
a2
uxx= utt
a2(uxx+ uyy) = utt
a2
(uxx+ uyy+ uzz) = utt
Now let us consider the steady-state solutions of these heat conduction and
wave equations. In each case, the steady-state solution, being independent
of time, must have all zero as its partial derivatives with respect to t.
Therefore, in every instance, the steady-state solution can be found bysetting, respectively, utor uttto zero in the heat conduction or the wave
equations and solve the resulting equation. That is, the steady-state solution
of a heat conduction equation satisfies
22u= 0,
and the steady-state solution of a wave equation satisfies
a22u= 0.
In all cases, we can divide out the (always positive) coefficient 2or a
2from
the equations, and obtain a universal equation:
2u= 0.
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This universal equation that all the steady-state solutions of heat conduction
and wave equations have to satisfy is the Laplace/potential equation!
Consequently, the 1-, 2-, and 3-dimensional Laplace equations are,respectively,
uxx= 0,
uxx+ uyy= 0,
uxx+ uyy+ uzz= 0.
Therefore, the Laplace equation, among other applications, is used to solve
the steady-state solution of the other two types of equations. And all
solutions of a Laplace equation are steady-state solutions. To answer the
earlier question, we have had seen and used the one-dimensional Laplace
equation (which, with only one independent variable,x, is a very simple
ordinary differential equation, u = 0, and is not a PDE) when we were
trying to find the steady-state solution of the one-dimensional homogeneous
heat conduction equation earlier.
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Laplace Equation for a rectangular region
Consider a rectangular region of length aand width b. Suppose the top,
bottom, and left sides border free-space; while beyond the right side therelies a source of heat/gravity/magnetic flux, whose strength is given byf(y).
The potential function at any point (x,y) within this rectangular region,
u(x,y), is then described by the boundary value problem:
(2-dim. Laplace eq.) uxx+ uyy= 0, 0
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=
X
X X =X X X= 0,
=
Y
Y Y = Y Y +Y= 0.
The boundary conditions also separate:
u(x,0) = 0 X(x)Y(0) = 0 X(x) = 0 or Y(0) = 0
u(x,b) = 0 X(x)Y(b) = 0 X(x) = 0 or Y(b) = 0
u(0,y) = 0 X(0)Y(y) = 0 X(0) = 0 or Y(y) = 0
u(a,y) =f(y) X(a)Y(y) =f(y) [cannot be simplified further]
As usual, in order to obtain nontrivial solutions, we need to ignore the
constant zero function in the solution sets above, and instead choose
Y(0) = 0, Y(b) = 0, andX(0) = 0 as the new boundary conditions. The
fourth boundary condition, however, cannot be simplified this way.
So we shall leave it as-is. (Dont worry. It will play a useful role
later.) The result, after separation of variables, is the following
simultaneous system of ordinary differential equations, with a set of
boundary conditions:
X X= 0, X(0) = 0,
Y +Y= 0, Y(0) = 0 and Y(b) = 0.
Plus the fourth boundary condition, u(a,y) =f(y).
The next step is to solve the eigenvalue problem. Notice that there is
another slight difference. Namely that this time it is the equation of Ythat
gives rise to the two-point boundary value problem which we need to solve.
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Y +Y= 0, Y(0) = 0, Y(b) = 0.
However, except for the fact that the variable isyand the function is Y,
rather thanxandX, respectively, we have already seen this problem before
(more than once, as a matter of fact; here the constantL= b). Theeigenvalues of this problem are
2
222
b
n == , n= 1, 2, 3,
Their corresponding eigenfunctions are
bynYn sin= , n= 1, 2, 3,
Once we have found the eigenvalues, substituteinto the equation ofx. We
have the equation, together with one boundary condition:
02
22
= Xb
nX
, X(0) = 0.
Its characteristic equation, 02
222 =
b
nr
, has real roots
b
nr
= .
Hence, the general solution for the equation ofxis
xb
nx
b
n
eCeCX
+= 21 .
The single boundary condition gives
X(0) = 0 = C1+ C2 C2= C1.
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Therefore, for n= 1, 2, 3, ,
=
x
b
nx
b
n
nn eeCX
.
Because of the identity of hyperbolic sine function
2sinh
= ee
,
the previous expression is often rewritten in terms of hyperbolic sine:
b
xnKX nn
sinh= , n= 1, 2, 3,
The coefficients satisfy the relation: Kn= 2Cn.
Combining the solutions of the two equations, we get the set of solutions
that satisfies the two-dimensional Laplace equation, given the specified
boundary conditions:
b
yn
b
xnKyYxXyxu nnnn
sinsinh)()(),( ==
,
n= 1, 2, 3,
The general solution, as usual, is just the linear combination of all the above,
linearly independent, functions un(x,y). That is,
b
yn
b
xnKyxu n
n
sinsinh),(
1
=
=.
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This solution, of course, is specific to the set of boundary conditions
u(x,0) = 0, and u(x,b) = 0,
u(0,y) = 0, and u(a,y) =f(y).
To find the particular solution, we will use the fourth boundary condition,
namely, u(a,y) =f(y).
)(sinsinh),(1
yfb
yn
b
anKyau n
n
==
=
We have seen this story before, and there is nothing really new here. The
summation above is a sine series whose Fourier sine coefficients are
bn=Knsinh(an/b). Therefore, the above relation says that the last
boundary condition,f(y), must either be an odd periodic function (period =
2b), or it needs to be expanded into one. Once we havef(y) as a Fourier sine
series, the coefficientsKnof the particular solution can then be computed:
==b
nn dyb
ynyfb
bb
anK0
sin)(2sinh
Therefore,
==b
nn dy
b
ynyf
b
anb
b
an
bK
0
sin)(
sinh
2
sinh
.
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(Optional topic) Laplace Equation in Polar Coordinates
The steady-state solution of the two-dimensional heat conduction or wave
equation within a circular region (the interior of a circular disc of radius k,that is, on the region r< k) in polar coordinates, u(r, ), is described by the
polar version of the two-dimensional Laplace equation
011
2 =++ u
ru
ru rrr .
The boundary condition, in this set-up, specifying the condition on the
circular boundary of the disc, i.e., on the curve r= k, is given in the formu(k, ) =f(), wherefis a function defined on the interval [0, 2). Note that
there is only one set of boundary condition, prescribed on a circle. This will
cause a slight complication. Furthermore, the nature of the coordinate
system implies that uandfmust be periodic functions of , of period 2.
Namely, u(r, ) = u(r, + 2), andf() =f(+ 2).
By letting u(r, ) =R(r)(), the equation becomes
011
2 =++ R
rR
rR .
Which can then be separated to obtain
=
=
+ RrRr2
.
This equation above can be rewritten into two ordinary differential equations:
r2
R + rR R= 0,
+ = 0.
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The eigenvalues are not found by straight forward computation. Rather,
they are found by a little deductive reasoning. Based solely on the fact that
must be a periodic function of period 2, we can conclude that= 0 and
= n2, n= 1, 2, 3, are the eigenvalues. The corresponding eigenfunctions
are 0= 1 and n=Ancos n+Bnsin n. The equation of ris anEulerequation(the solution of which is outside of the scope of this course).
The general solution of the Laplace equation in polar coordinates is
( )
=
++=1
0 sincos2
),(n
n
nn rnBnAA
ru .
Applying the boundary condition u(k, ) =f(), we see that
( ) )(sincos2
),(1
0 fnkBnkAA
kun
n
n
n
n =++=
=.
Sincef() is a periodic function of period 2, it would already have a
suitable Fourier series representation. Namely,
( )
=
++=1
0 sincos2
)(n
nn nbnaa
f .
Hence,A0= a0, An= an/kn, and Bn= bn/k
n, n= 1, 2, 3
For a problem on the unit circle, whose radius k= 1, the coefficientsAnand
Bnare exactly identical to, respectively, the Fourier coefficients anand bnof
the boundary conditionf().
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(Optional topic)Undamped Wave Equation in Polar Coordinates
The vibrating motion of an elastic membrane that is circular in shape can be
described by the two-dimensional wave equation in polar coordinates:
urr+ (1/r)ur+ (1/r2) u= a
2utt.
The solution is u(r, , t), a function of 3 independent variables that describes
the vertical displacement of each point (r, ) of the membrane at any time t.